KR101532258B1 - Injection device - Google Patents

Abstract

An injection device comprises a locking mechanism between a syringe carrier (127, figure 3) and a drive mechanism (129, figure 3) of the injection device. The syringe carrier is connected to a latch actuator 137a from which locking arms 171 extend to engage a locking surface 172 on the drive mechanism, such that the syringe carrier can not be moved forward without corresponding forward motion of the drive mechanism. The drive is secured in place by a locking trigger arrangement (102, figure 2a) which bears on the housing of the device. Only when the trigger is released can the drive operate and so move the syringe carrier into its operational position.

Description

[0001] INJECTION DEVICE [0002]

The present invention relates to a scanning device of the type having a syringe and extending the syringe to eject its contents and then automatically retract the syringe.

The scanning device is disclosed in WO 95/35126 and EP-A-0 516 473. These devices utilize a drive spring and a release mechanism of some type for releasing the syringe from the influence of the drive spring once its contents have been discharged and allowing the syringe to be retracted by the return spring.

In general, the return spring is relatively weak, because its restoring force must be overcome by the drive spring while the drive spring is operating on the various parts of the scanning device and the syringe during the scan cycle. This can cause problems when the scanning device is used with a sealed hypodermic syringe, which typically covers the dermal needle and provides a hermetically sealed cover, needle shield or "boot " " In general, it is necessary to maintain sterility of the contents of the syringe to the point of administration, which means that for devices designed for single use as such, the boot must be removed with the syringe inside the scanning device.

Typically, the action required to remove the boot from the syringe is simply to pull the boot away from the syringe, which requires a force in excess of 20 N. This is considerably greater than the restoring force of the return spring so that the syringe will be pulled from the scanning device as the boot is removed and will snap in place when the boot is spaced apart. This is not the best way to handle a syringe. Impact can damage the syringe, damage the needle, and there may be a problem with reassembly of the syringe with the part of the scanning device designed to act on the syringe. In the absence of a return spring, there will still be a problem of relocating the syringe on the part of the scanning device designed to act on the syringe, for example if the syringe is held in place by friction with the part of the scanning device .

Furthermore, there is the problem of having a generally movable syringe in the direction of the exterior of the scanning device. Accidental actuation of the drive spring due to mechanical failure of the release mechanism of the drive spring (e.g., trigger) may occur, for example, by dropping the device onto a hard surface. This contingent operation may unintentionally extend the syringe from the device to cause its contents to be drained. This may expose the needles of the syringe and increase the risk of unintended ski perforation and / or infection.

The scanning device of the present invention is designed to handle the aforementioned problems.

In a first aspect of the present invention,

A housing configured to receive a syringe having an ejection nozzle wherein the syringe is movable within a housing along a longitudinal axis from a retracted position in which the ejection nozzle is housed within the housing to an extended position in which the ejection nozzle of the syringe extends from the housing through an exit aperture, A housing,

An actuator,

A drive actuated by an actuator and subsequently acting on the syringe to advance the syringe from its retracted position to its extended position and eject its contents through the discharge nozzle,

A syringe carrier configured to support the syringe when advancing, and

There is provided a scanning device including a syringe carrier facing the exit aperture when the syringe is in its retracted position and a fastening mechanism between the syringe carrier and the drive configured to inhibit movement of the syringe.

Thus, the syringe carrier and the syringe can not move toward the exit aperture prior to actuation of the scanning device. Since the fastening mechanism is manufactured in the drive, a separate, independent fastening mechanism is not required. The syringe carrier is automatically uncoupled when the drive moves and moves the syringe and syringe carrier to the extended position (i.e., movement toward the exit aperture is allowed). By preventing movement of the syringe carrier from the exit aperture (which is not in the operating sequence of the scanning device), damage to the syringe and its contents is prevented. Moreover, this helps to prevent accidental actuation of the scanning device, for example by dropping the scanning device on a hard surface.

Preferably, the scanning device includes a releasing mechanism for preventing the actuator from acting on the drive at the engaged position and allowing the actuator to act on the drive at the disengaged position, wherein the engaging mechanism is configured such that when the releasing mechanism is in its engaged position To prevent movement of the syringe carrier toward the exit aperture.

Preferably, the fastening mechanism comprises at least one arm fixed relative to the syringe carrier, and the arm is engageable with a corresponding fastening surface on the drive.

In one embodiment of the invention, the fastening mechanism comprises a plurality of arms on a circumferentially spaced syringe carrier around the drive. This provides improved fastening for movement of the syringe towards the exit aperture.

Advantageously, the arms may be equidistantly spaced around the drive.

In a particular embodiment of the invention, the fastening mechanism comprises two arms.

Preferably, each arm is flexible and / or resilient. This allows the drive to be inserted into the syringe through the end of the syringe carrier because the arm is bent outwardly. More preferably, each arm projects in a direction toward the longitudinal axis.

Preferably, each arm is positioned and oriented to contact the locking surface on the drive to prevent movement of the syringe carrier in the longitudinal direction toward the exit aperture.

The scanning device has a proximal end adjacent the exit aperture and a distal end located at an opposite end of the scanning device along the longitudinal axis.

In one embodiment of the invention, the fastening surface is formed between the first section of the drive and the second section of the drive, the second section of the drive is positioned towards the distal end of the drive with respect to the first section, And is formed at an intersection between the first and second sections of the drive.

Preferably, the first section of the drive is positioned closer to the exit aperture than the at least one arm. The second section of the drive may be narrower about the longitudinal axis than the first section of the drive.

Preferably, the engaging surface is formed by a surface that is not parallel to the longitudinal direction.

More preferably, the engaging surface is formed by a surface perpendicular to the longitudinal direction.

In certain embodiments of the invention, the drive includes a shaft extending along a longitudinal axis.

Preferably, the actuator includes a deflection means configured to deflect the syringe carrier from a retracted position to an extended position.

The arrangement of the drive and the arm allows the wider proximal end of the drive to pass through the arm to a point where a narrower section of the drive is located adjacent the arm. At this point, the arms are bent back to their normal, un-tilted position, thereby preventing the wider proximal end of the drive from passing back through the syringe carrier from the syringe. This also means that the syringe carrier can not move towards the exit aperture unless it moves with the drive.

In one embodiment of the invention, the drive comprises first and second driving elements, of which the first driving element is actuated by the actuator and then acts on the second driving element, and the second driving element is the syringe Acting on the syringe carrier to cause the syringe to advance from its retracted position to its extended position and eject its contents through the discharge nozzle, the first drive element being actuated by the actuator and the second drive element being actuated by the syringe or syringe carrier When confined, the first driving element can move relative to the second driving element.

Advantageously, the scanning device includes a coupling that prevents the first driving element from moving relative to the second driving element until it is advanced to a nominally separated position that is less advanced than the nominally released position.

Advantageously, the coupling is configured to be actuated when the drive elements are advanced to the nominally disengaged position and configured to separate the first drive element from the second drive element such that the first drive element is movable relative to the second drive element Mechanism.

In one embodiment of the invention, the scanning device further comprises a cap removably disposed on the exit aperture.

Preferably, the scanning device includes a needle shield disposed removably on the discharge nozzle.

The cap is configured to grasp the needle shield so that the needle shield is removed from the discharge nozzle while the cap is removed from the housing.

The present invention will now be described, by way of example, with reference to the accompanying drawings.

According to the present invention, by preventing movement of the syringe carrier from the exit opening, damage to the syringe and its contents can be prevented. Moreover, this can help prevent accidental actuation of the scanning device, for example by dropping the scanning device on a hard surface.

1A is a right side view of a scanning device according to the present invention.
1B is a perspective view of the scanning device of Fig. 1 with its cap removed; Fig.
Figure 1C is a perspective view of the cap of the scanning device of Figure 1;
Figure 2a is an exploded right side view of the scanning device of Figure 1;
Figure 2B is a right side view of the assembled component of the scanning device of Figure 1;
Figure 2c is a perspective view of the multiple part drive used in the scanning device of Figure 1;
Figure 3 is a cross-sectional view of the scanning device of Figure 1;

1A is a right side view of a scanning device 110 according to the present invention. The scanning device 110 has a housing 112, a removable cap 111 and a trigger button 102 from the proximal end 167 of the housing 112. Other parts of the device will be described in more detail below.

1B is a perspective view of a scanning device 110 according to the present invention in which a cap (not shown) is removed from its end. The end of the housing 112 has an exit aperture 128 from which the end of the sleeve 119 can be seen to appear.

1C is a perspective view of a cap 111 of a scanning device 110 according to the present invention. The cap 111 has a central boss 121 that fits within the sleeve 119 when the cap 111 is installed on the housing 112.

2A is a right side view of the components of the scanning device 110 according to the present invention and FIG. 2B is a right side view of the assembled components of the scanning device 110 according to the present invention without the housing 112 or the cap 111. FIG. to be.

As shown, the scanning device 110 includes a syringe body 116 terminating at one end in the discharge nozzle (specifically, the dermal needle 118) and terminating at the other end in the flange 120 Lt; RTI ID = 0.0 > 114 < / RTI > A conventional plunger that can be used to dispense the contents of the syringe 114 is manually removed to form a drive element (hereinafter referred to as a second drive element 134) that contacts the bung 122 in the syringe 114 Quot;). The stop 122 restrains the drug (not shown) to be injected into the syringe body 116. The illustrated syringe is a subcutaneous, but it need not be a subcutaneous. Percutaneous or ballistic dermis and hypodermic syringes may also be used with the scanning device of the present invention.

As shown, the scanning device 110 is configured such that the needle 118 is positioned within the housing 112 in an extended position in which the needle 118 extends from the aperture 128 in the case nose 112a of the housing 112 And a return spring 126 for deflecting the syringe 114 to a retracted position to be accommodated. The return spring 126 acts on the syringe 114 via the syringe carrier 127. The syringe 114 includes a longitudinal axis 105 of the scanning device 110 that extends centrally along the length of the scanning device 110 from the exit aperture 128 of the proximal end 167 to the distal end 168 Can be moved along.

The actuator contained within the housing at its distal end 168 includes deflecting means configured to deflect the syringe carrier 127 from its retracted position to its extended position. The deflection means takes the form of a compression drive spring 130 here. The driving force from the drive spring 130 is transmitted to the syringe 114 via the multi-part drive 129 to advance the syringe from its retracted position to its extended position and eject its contents through the needle 118. The drive 129 accomplishes this task by acting directly on the drug and syringe 114. The static friction between the stop 122 and the syringe body 116 at the water pressure acting through the drug and to a lesser extent is such that initially the return spring 126 contacts the floor on the syringe carrier 127, Thereby ensuring that these stoppers and the syringe body advance together until they meet some other obstacle (not shown).

2C is an exploded perspective view of the multi-part drive 129. FIG. The multi-part drive 129 between the drive spring 130 and the syringe 114 consists of three major components. The drive sleeve 131 takes the drive force from the drive spring 130 and delivers it to the delay piston 133 on the first drive element 132. Which in turn transfers the driving force to the second driving element 134. 2C, the first drive element 132 and the second drive element 134 of the drive 129 include a shaft that extends along the longitudinal axis 105. In this embodiment,

As can be seen from Figure 2c, the first actuating element 132 includes a hollow stem 140, the inner cavity of which is passed from the collection chamber 141 through the end of the stem 140 Thereby forming a collection chamber 141 communicating with the extending vent 144. The second driving element 134 includes a blind bore 146 that is open at one end to receive the stem 140 and closed at the other end. As can be appreciated, the bore 146 and stem 140 form a fluid reservoir within which the damping fluid is contained.

A trigger button 102 is provided on the side of the housing 112 when the trigger button is in its engaged position with the proximal end 145 of the drive sleeve 131 and when the trigger button 102 is in the inoperative position And serves to hold the drive spring 130 in a compressed state by the contact between the engaging surface 102b and the drive sleeve 131. [ The trigger button 102 can pivot on the housing 112 via the pivot 102a. When the downward pressure (i.e., the pressure directed into the housing 112) is applied to the trigger button 102 at the actuation surface 102c, the engagement surface 102b moves upwardly in a direction away from the longitudinal axis 105 Move. In this activated position of the trigger button 102 the engagement surface 102b is disengaged from the drive sleeve 131 so that the drive sleeve 131 is urged toward the exit aperture 128 under the influence of the drive spring 130 To move relative to the housing 112.

The sliding sleeve 119 is movable into its retracted position in the case nose 112a of the housing 112 from its extended position (as shown in Fig. The sliding sleeve 119 is connected to a trigger button engaging element 150 having an elastic arm 151 that displaces the sliding sleeve 119 from its end to an extended position where it protrudes from the end of the case nose 112a. Thus, applying pressure to the end of the sliding sleeve 119, for example by pressing the end of the sliding sleeve 119 against the tissue, causes the sliding sleeve to move to its retracted position in the housing 112, The release causes the sliding sleeve 119 to move to its extended position under the bias from the resilient arm 151 acting against the side wall of the housing 112. The trigger button engagement element 150 has a trigger button engagement projection 152 that contacts the end of the trigger button projection 102d on the trigger button 102 when the sliding sleeve is in its extended position. The trigger button protrusion 102 extends in a direction generally parallel to the longitudinal axis 105 of the scanning device 110. The trigger button engagement protrusion 152 extends in a direction generally perpendicular to the longitudinal axis 105 toward the trigger button protrusion 102d. Trigger button protrusion 102d is configured such that when trigger button engagement element 150 is moved away from exit aperture 128 (i.e., when sliding sleeve 119 is moved into its retracted position into exit aperture 128) And a hole 102e that can move to the upper portion of the trigger button engagement protrusion 152. [ In this position, the trigger button 102 can be moved to its inoperative position by rotating the trigger button 102 about the pivot 102a in the direction of the pressure applied to the pressure surface 102c. Thus, the trigger button engagement element 150 and the sliding sleeve 119 together act to secure the trigger button 102 to its operative position (i.e., the engagement surface 102b contacts the end of the drive sleeve 131) Thereby preventing the drive sleeve from moving toward the exit hole 128 under the bias of the compressed drive spring 130).

When the sliding sleeve 119 is moved to the retracted position (i.e., its unlocked position) into the housing 112 and the trigger button 102 is rotated to its inoperative position, .

Initially, the drive spring 130 moves the drive sleeve 131 by acting through the flexible latch arms 132a, 134a, 134b in each case, and the drive sleeve 131 moves the first drive element 132, And the first driving component 132 moves the second driving component 134. The second drive element 134 moves and moves the syringe body 116 and the syringe carrier 127 against the action of the return spring 126 by static friction and water pressure acting through the drug (not shown) . The return spring 126 is compressed and the dermal needle 118 emerges from the exit aperture 128 of the housing 112. [ This continues until the return spring 126 touches the floor or the syringe body 116 meets some other obstacle (not shown) that delays its movement. Since the static friction between the second driving element 134 and the syringe body 116 and the purified pressure acting through the drug (not shown) to be administered are not sufficient to resist the total driving force generated by the driving spring 130 , At which point the second drive element 134 begins to move within the syringe body 116 and the drug (not shown) begins to drain. However, the static pressure acting through the dynamic friction between the second driving element 134 and the syringe body 116 and the drug (not shown) to be administered is sufficient to hold the return spring 126 in its compressed state, Thus, the dermal needle 118 is maintained in an extended state.

Before the second drive element 134 reaches the end of its movement in the syringe body 116 and thus before the contents of the syringe are completely ejected the first and second drive elements 132 and 134 are connected The flexible latch arms 134a and 134b reach the constriction 137 provided on the latch actuator element 137a secured to the end of the syringe carrier 127. [ The constriction portion 137 is moved from the position shown in Figure 2c such that the flexible latch arms 134a and 134b assisted by the inclined surface on the constriction 137 no longer move the first driving element 132 to the second driving element 134, To move the flexible latch arms 134a, 134b inwardly to a position that does not engage the latches 134a, 134b. Once this movement has occurred, the first driving element 132 no longer acts on the second driving element 134, so that the first driving element 132 can move relative to the second driving element 134 do.

Because the damping fluid is contained within a reservoir (not shown) formed between the end of the first drive element 132 and the blind bore 146 in the second drive element 134, the volume of the reservoir is such that the first drive element May tend to decrease as the first actuating element 132 moves relative to the second actuating element 134 when acted upon by the second actuating element 130. As the reservoir collapses, the damping fluid moves through the vents 144 to the collection chamber 141 forcibly. Thus, once the flexible latch arms 134a, 134b are released, a force applied by the drive spring 130 acts on the damping fluid, causing the damping fluid to flow through the constriction formed by the vent 144 , And also acts hydrostatically via the fluid and via the second driving element 134 from there through friction between the first and second driving elements 132, 134. The loss associated with the flow of the damping fluid does not significantly dampen the force acting on the body of the syringe. Thus, the return spring 126 is kept in a compressed state, and the dermal needle is maintained in an extended state.

Thereafter, the second driving element 134 completes its movement in the syringe body 116 and does not proceed any further. At this point the contents of the syringe 114 are completely drained and the force applied by the drive spring 130 holds the second drive element 134 at its end position and the damping fluid continues to flow through the vents 144 So that the first driving element 132 continues its movement.

The flexible latch arm 132a connecting the drive sleeve 131 to the first drive element 132 reaches another constriction (not shown) in the housing 112 before the fluid reservoir is depleted. The narrowed portion moves the flexible latch arm 132a inwardly from the position shown in the first driving element 132, which is assisted by the slope on the narrowed portion, to a position where they no longer engage the driving sleeve 131. Once this movement occurs, the drive sleeve 131 no longer acts on the first drive element 132, allowing them to move relative to each other. At this point, of course, the syringe 114 is released, because the force generated by the drive spring 130 is no longer transmitted to the syringe 114 and only the force acting on the syringe is from the return spring 126 It will be a return. Thus, the syringe 114 is now returned to its retracted position and the scan cycle is complete.

All of this occurs only once the cap 111 is removed from the end of the housing 112. The end of the syringe is sealed with a needle shield in the form of a boot 123. The center boss 121 of the cap that fits within the sleeve 119 when the cap 111 is installed on the housing 112 includes a retainer element 125 secured within the boss 121. The retainer element 125 includes an elastic projection 125a that is directed away from the exit aperture 128. These elastic projections 125a are deformed as the cap 111 is inserted into the needle shield or the housing 112 on the rubber boot 123. The protrusion 125a is then slightly gripped by the boot 123 so that the end of the protrusion is slightly buried in the boot 123, which can be made of rubber. This means that when the cap 111 is pulled from the housing 112, the boot 123 is pulled from the syringe 114 together with the cap 111. [

Figure 3 illustrates how the fastening mechanism 170 is formed integrally with the scanning device 110 of the present invention.

Since the fastening mechanism 170 is located on the latch actuator element 137a so that the fastening mechanism is always located between the syringe carrier 127 and the drive 129 so that the drive 129 itself does not move in this direction, The movement of the syringe carrier 127 and the syringe 114 toward the proximal end 167 of the syringe barrel 167 is inhibited.

The fastening mechanism includes a plurality of arms 171 secured to the latch actuator element 137a such that a plurality of arms 171 are secured relative to the syringe carrier 127. Each arm is engageable with a corresponding engaging surface 172 on the drive 129. The arms 171 are circumferentially spaced equidistantly about the longitudinal axis 105.

Each arm 171 is flexible, thereby allowing the drive 129 to be inserted into the distal end of the syringe 114 during assembly of the device. Each arm 171 projects along a longitudinal axis toward the longitudinal axis 105 and toward the proximal end 167 of the scanning device 110 (i.e., at an angle of inclination relative to the longitudinal axis 105) do. Which is positioned and oriented so that the arm 171 contacts the engagement surface 172 on the drive 129 to move the syringe carrier 127 and syringe 114 toward the exit aperture in a direction parallel to the longitudinal axis 105 .

The engaging surface 172 is formed between the first section 173a of the drive and the second section 173b of the drive 129 and specifically on the second driving element 134. [ The second section 173b of the drive 129 is positioned toward the distal end 168 of the scanning device 110 with respect to the first section 173a. A fastening surface 172 is formed on the surface connecting the first and second sections 173a, 173b of the drive 129. The first section 173a of the drive is positioned closer to the proximal end 167 of the scanning device 110 than the arm 171. [ The second section 173b of the drive is narrower about the longitudinal axis 105 than the first section 173a of the drive thereby forming a ridge for the fastening surface 172 in the drive 129.

When an attempt is made to move the syringe carrier 127 and the syringe 114 in the direction toward the proximal end 167 of the scanning device 110 (when such movement does not pass through the drive 129, (When removing the cap 111 by pulling it in a direction away from the proximal end 167 of the body 112), the arm 171 comes into contact with the engagement surface 172, but passes through the engagement surface 172 I can not. This means that the force pulling the syringe 114 in the direction toward the proximal end 167 is transmitted to the engagement surface 102b on the button 102 via the drive 129. This prevents the syringe 114 and the syringe carrier 127 from moving in the longitudinal direction unless the syringe 114 and the syringe carrier 127 are actuated through the movement of the drive 129.

Of course, it is to be understood that the invention has been described above by way of example only, and that modifications of detail can be made within the scope of the invention.

Claims (23)

As a scanning device,
A housing configured to receive a syringe having an ejection nozzle, the syringe being movable from a retracted position in which the ejection nozzle is received within the housing to an extended position in which the ejection nozzle of the syringe extends from the housing through the exit aperture, A housing movable within the housing;
An actuator,
A drive actuated by the actuator and subsequently acting on the syringe to advance the syringe from its retracted position to its extended position and to discharge its contents through the discharge nozzle;
A syringe carrier configured to support the syringe when advanced, and
And a fastening mechanism between the syringe carrier and the drive to inhibit movement of the syringe carrier and the syringe toward the exit aperture. 2. The assembly of claim 1, further comprising a release mechanism to prevent the actuator from acting on the drive at the engagement position and to allow the actuator to act on the drive at the release position, Is configured to prevent movement of the syringe carrier toward the exit aperture when in its engaged position. 3. A scanning device according to claim 1 or 2, wherein said fastening mechanism comprises at least one arm fixed relative to said syringe carrier, said arm being engageable with a corresponding fastening surface on said drive. 4. The scanning device of claim 3, wherein the fastening mechanism comprises a plurality of arms on a circumferentially spaced syringe carrier about the drive. 5. The scanning device of claim 4, wherein the arms are equidistantly spaced about the drive. 4. The scanning device according to claim 3, wherein the fastening mechanism comprises two arms. 4. The scanning device according to claim 3, wherein the at least one arm is flexible. 4. The scanning device according to claim 3, wherein the at least one arm projects in a direction toward the longitudinal axis. 4. The scanning device of claim 3, wherein the at least one arm is positioned and oriented to contact a fastening surface on the drive to prevent movement of the syringe carrier in a longitudinal direction toward the exit aperture. 4. The scanning device of claim 3, wherein the scanning device has a proximal end adjacent the exit aperture and a distal end located at an opposite end of the scanning device along the longitudinal axis. 11. The assembly of claim 10, wherein the engaging surface is formed between a first section of the drive and a second section of the drive, and wherein a second section of the drive is positioned toward a distal end of the drive relative to the first section ,
Wherein the engaging surface is formed at an intersection between the first and second sections of the drive. 12. The scanning device of claim 11, wherein the first section of the drive is positioned closer to the exit aperture than the at least one arm. 12. The scanning device of claim 11, wherein the second section of the drive is narrower than the first section of the drive about the longitudinal axis. 12. The scanning device according to claim 11, wherein the engaging surface is formed by a surface that is not parallel to the longitudinal direction. 15. The scanning device according to claim 14, wherein the engaging surface is formed by a surface perpendicular to the longitudinal direction. 16. The scanning device of claim 15, wherein the drive includes a shaft extending along the longitudinal axis. 3. A scanning device according to claim 1 or 2, wherein the actuator comprises deflecting means configured to deflect the syringe carrier from a retracted position to an extended position. 3. The apparatus of claim 1 or 2, wherein the drive comprises first and second driving elements, wherein a first driving element is actuated by the actuator and then acts on a second driving element, The element being operative on the syringe or syringe carrier to cause the syringe to advance from its retracted position to its extended position and to discharge its contents through the discharge nozzle, and wherein the first actuating element is actuated by the actuator and the second Wherein the first drive element is movable relative to the second drive element when the drive element is constrained by the syringe or syringe carrier. 19. The scanning device of claim 18, further comprising a coupling to prevent the first driving element from moving relative to the second driving element until it is advanced to a nominally separated position that is less advanced than the nominal release position. 20. The apparatus of claim 19, wherein the coupling comprises a detachment mechanism, the detachment mechanism being configured to operate when the drive elements are advanced to the nominally disengaged position and to separate the first drive element from the second drive element Wherein the first drive element is movable relative to the second drive element. 3. A scanning device according to claim 1 or 2, further comprising a cap removably disposed on the exit aperture. 22. The scanning device of claim 21, further comprising a needle shield removably disposed on the discharge nozzle. 23. The scanning device of claim 22, wherein the cap is configured to grasp the needle shield so that the needle shield is removed from the discharge nozzle while the cap is removed from the housing.

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